JP2002174465A - Refrigerating apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerating apparatus, in which refrigerating machine oil is easy to return to a compressor. SOLUTION: In a refrigerant circuit (20) on the high temperature side, the piping is arranged so that the refrigerant flows from the below to the upside in an indoor heat-exchanger (81), and the refrigerant flows from the upside to the downside in an evaporator (101) for refrigeration, and further the refrigerant flows from the upside to downside in a primary side flow path (111a) of a cascade heat exchanger (111). While in the refrigerant circuit on the low temperature side, the piping is arranged so that the refrigerant flows from the upside to the downside in an evaporator for refrigeration.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a refrigeration apparatus,
In particular, it concerns oil return measures.

[0002]

2. Description of the Related Art Conventionally, a refrigerating apparatus has been disclosed in, for example, Japanese Patent Application Laid-Open No. 2000-39230.
A heat exchanger that is installed in supermarket stores and supplies relatively high-temperature cold heat and is used for indoor cooling, and supplies relatively low-temperature cold heat to cool or freeze foodstuffs And a refrigerant circuit having a heat exchanger used for the above. In this type of refrigeration apparatus, the heat exchanger serving as an evaporator is connected to a pipe so that the refrigerant flows upward from below, so that the evaporated refrigerant flows smoothly.

[0003]

However, there has been a problem that the refrigerating machine oil tends to accumulate in the refrigerating or freezing heat exchanger and it is difficult to return to the compressor. That is, in a refrigerator or a freezer, the temperature in the refrigerator is adjusted to a low temperature, the fluctuation in the temperature in the refrigerator is small, and the load is small, so that the amount of refrigerant flowing through the refrigeration or freezing heat exchanger is reduced. Therefore,
If the refrigerant is connected to the refrigeration or freezing heat exchanger such that the refrigerant flows upward from below, the refrigerating machine oil does not evaporate in the heat exchanger, so that it becomes difficult to flow together with the refrigerant. As a result, the refrigerating machine oil easily accumulates in the heat exchanger,
There was a problem that it was difficult to return to the compressor.

[0004] The present invention has been made in view of such a point, and an object of the present invention is to make it easy for refrigeration oil to return to a compressor.

[0005]

According to the present invention, a refrigerant flows from an upper part to a lower part in a heat exchanger for supplying cold heat at a relatively bottom temperature.

Specifically, a first solution is to provide an air conditioning heat exchanger (81) in which refrigerant evaporates or condenses, and a low temperature heat exchanger in which refrigerant evaporates at a lower temperature than the air conditioning heat exchanger (81). Container (10
1,111a, 131) are connected in parallel, and the air-conditioning heat exchanger (81) is arranged so that the refrigerant flows from the lower part to the upper part during the cooling operation, The exchangers (101, 111a, 131) are arranged so that the refrigerant flows from the upper part to the lower part.

In a second aspect of the present invention, in the first aspect, the low-temperature heat exchanger comprises a refrigeration evaporator (101) for cooling air in the refrigerator.

[0008] A third solution is the primary solution circuit according to the first solution, further comprising an air-conditioning heat exchanger (81), and a primary-side refrigerant circuit (20) through which the primary-side refrigerant circulates. A secondary-side refrigerant circuit (25) having a refrigerating evaporator (131), while circulating a secondary-side refrigerant condensed by evaporation of the primary-side refrigerant of the primary-side refrigerant circuit (20); Secondary refrigerant and 2
A refrigerant heat exchanger (111) for exchanging heat with the refrigerant on the next side, wherein the low-temperature heat exchanger is formed by an evaporator (111a) and a refrigerating evaporator (131) of the refrigerant heat exchanger (111). It is configured.

A fourth solution is the third solution, wherein the primary refrigerant circuit (20) is provided with a compressor (41,4).
2) and a heat source side heat exchanger (32) and a heat source unit (11) to which a refrigeration evaporator (101) is connected, while a refrigerant heat exchanger (111) and an air conditioning heat exchanger (81)
Is connected to the heat source unit (11), and the air-conditioning heat exchanger (81) performs cooling operation by evaporating the primary-side refrigerant condensed in the heat source-side heat exchanger (32), and performs the cooling operation. The refrigerant on the primary side condensed in the heat exchanger (81) is cooled by the evaporator (10).
1) Or it is configured to perform a heating operation by evaporating in the evaporating section (111a) of the refrigerant heat exchanger (111).

That is, in the first solution, in the air-conditioning heat exchanger (81), the refrigerant flows from the lower part to the upper part and evaporates during the cooling operation. On the other hand, in the low-temperature heat exchangers (101, 111a, 131), the refrigerant flows from the upper part to the lower part and evaporates.

In the second solution, the first solution
In the resolving means, the refrigerant flows from the upper part to the lower part and evaporates in the refrigeration evaporator (101) for cooling the air in the refrigerator.

Further, in the third solution, the first solution is provided.
In the evaporating section (1) of the refrigerant heat exchanger (111).
In 11a), the refrigerant flows from the upper part to the lower part and evaporates, whereby the refrigerant on the secondary side is condensed. The condensed secondary-side refrigerant flows from the upper part to the lower part in the refrigerating evaporator (131) and evaporates.

Further, in the fourth solution, the third solution is provided.
In the first aspect, in the primary refrigerant circuit (20),
The air-conditioning heat exchanger (81) performs a cooling operation by evaporating the primary-side refrigerant condensed in the heat-source-side heat exchanger (32), while performing the primary-side refrigerant discharged from the compressor (41, 42). The refrigerant condenses and performs the heating operation. During heating operation, the air-conditioning heat exchanger (81)
The primary-side refrigerant condensed in the above evaporates in the evaporator (101) or the evaporator (111a) of the refrigerant heat exchanger (111).

[0014]

Therefore, according to the above solution, since the low-temperature heat exchangers (101, 111a, 131) having a small refrigerant flow rate are arranged so that the refrigerant flows from the upper part to the lower part and evaporates, the refrigeration is performed. Machine oil can be prevented from accumulating in the low-temperature heat exchangers (101, 111a, 131), and can easily return to the compressors (41, 42). As a result, there is no need to perform oil return control that sacrifices performance, and performance can be maximized.

Further, according to the third solution, in the evaporating section (111a) of the refrigerant heat exchanger (111), the primary-side refrigerant flows from the upper part to the lower part and evaporates,
In the refrigeration evaporator (131), since the secondary-side refrigerant flows from the upper part to the lower part and evaporates, the evaporator (111a) of the refrigerant heat exchanger (111) and the refrigeration evaporator (131) ) Can prevent refrigerating machine oil from accumulating in
The refrigerating machine oil can be easily returned to the compressor (41, 42).

According to the fourth solution, during the heating operation of the air-conditioning heat exchanger (81), the cold heat obtained from the room is supplied to the refrigeration evaporator (101) or the refrigerant heat exchanger (111). Since the heat is supplied to the evaporator (111a), the thermal efficiency can be improved.

[0017]

Embodiments of the present invention will be described below in detail with reference to the drawings. The refrigeration apparatus (10) according to the present embodiment is provided in a convenience store, a supermarket, or the like, and performs cooling of a refrigerator or a freezer and cooling and heating of a room.

As shown in FIGS. 1 and 2, a refrigerating apparatus (10) according to the present embodiment includes a high-temperature side refrigerant circuit (20) as a primary side refrigerant circuit and a low-temperature side refrigerant as a secondary side refrigerant circuit. The system includes a circuit (25) and a controller (200), and is configured to perform a so-called binary refrigeration cycle. The refrigeration apparatus (10) includes an outdoor unit (11), an indoor unit (12), a cooling unit (13), a refrigeration unit (14), a cascade unit (15), and a refrigeration unit (16), which are heat source units. It has.

The indoor unit (12) is configured to switch between cooling and heating. The indoor unit (12) is installed in, for example, a sales floor. The cooling unit (13) is configured to perform only cooling.
The cooling unit (13) is installed in a room having a heat load, such as a kitchen, and performs cooling throughout the year. The refrigeration unit (14) is installed in the refrigerator and cools air in the refrigerator. The refrigeration unit (16) is installed in the freezer and cools air in the freezer.

<< Structure of High Temperature Side Refrigerant Circuit >> The high temperature side refrigerant circuit (20) includes an outdoor circuit (30), an indoor circuit (80),
A cooling circuit (90), a refrigeration circuit (100), a high temperature side cascade circuit (110), a first liquid side communication pipe (21), a second liquid side communication pipe (23), and a first gas side communication. It is composed of a pipe (22) and a second gas side communication pipe (24). this house,
The indoor circuit (80) is connected to the outdoor circuit (30) via the first liquid side communication pipe (21) and the first gas side communication pipe (22). On the other hand, a cooling circuit (90), a refrigeration circuit (100),
The high temperature side cascade circuit (110) is the second liquid side communication pipe (2
3) and the outdoor circuit (3) through the second gas side communication pipe (24).
0) are connected in parallel. The high temperature side refrigerant circuit (20) is filled with a high temperature side refrigerant which is a primary side refrigerant.

The outdoor circuit (30) includes an outdoor unit (1).
It is stored in 1). The outdoor circuit (30) includes a compressor unit (40), a four-way switching valve (31), an outdoor heat exchanger (32) that is a heat source side heat exchanger, an outdoor expansion valve (34), and a receiver ( 33), a first liquid side closing valve (35), a second liquid side closing valve (37), a first gas side closing valve (36), and a second gas side closing valve (38). I have. The outdoor circuit (30) is provided with a gas vent pipe (64), a pressure equalizing pipe (66), and a liquid supply pipe (68).

The compressor unit (40) has a first compressor (41) and a second compressor (42) connected in parallel. Each of the first compressor (41) and the second compressor (42) is a closed-type, high-pressure dome-type scroll compressor. That is, these compressors (41, 42) are configured by housing a compression mechanism and an electric motor that drives the compression mechanism in a cylindrical housing. The illustration of the compression mechanism and the electric motor is omitted. The first compressor (41) has a variable capacity in which the number of revolutions of the electric motor is changed stepwise or continuously. Second
The compressor (42) has a constant capacity in which the electric motor is always driven at a constant rotation speed. The capacity of the entire compressor unit (40) is variable by changing the capacity of the first compressor (41) or starting and stopping the second compressor (42).

The compressor unit (40) is provided with a suction pipe (4
3) and a discharge pipe (44). The suction pipe (43)
The inlet end is connected to the first port of the four-way switching valve (31), and the outlet end is branched into two, and each of the compressors (41, 42)
Is connected to the suction side. The discharge pipe (44) has an inlet end branched into two and connected to the discharge side of each compressor (41, 42), and an outlet end connected to the second port of the four-way switching valve (31). Have been. Further, a discharge-side check valve (45) is provided in a branch pipe of the discharge pipe (44) connected to the second compressor (42). The discharge-side check valve (45) allows only the flow of the refrigerant in the direction flowing out of the second compressor (42).

The compressor unit (40) includes an oil separator (51), an oil return pipe (52), and an oil equalizing pipe (54). The oil separator (51) is provided in the middle of the discharge pipe (44). This oil separator (51) is a compressor (41,42)
To separate the refrigerating machine oil from the discharged refrigerant.
The oil return pipe (52) has one end connected to the oil separator (51) and the other end connected to the suction pipe (43). The oil return pipe (52) is for returning the refrigerating machine oil separated by the oil separator (51) to the suction side of the compressors (41, 42), and is provided with an oil return solenoid valve (53). Have. Equalizing oil pipe (54)
Has one end connected to the second compressor (42) and the other end connected to the suction pipe (43) near the suction side of the first compressor (41). This oil equalizing pipe (54) is connected to each compressor (4
This is for averaging the amount of refrigerating machine oil stored in the housing of (1), (42), and includes an oil equalizing solenoid valve (55).

The four-way switching valve (31) has a third port connected to the first gas side shut-off valve (36) by a pipe, and a fourth port.
Port is connected to the upper end of the outdoor heat exchanger (32) by piping. The four-way switching valve (31) has a state in which the first port and the third port are in communication and the second port and the fourth port are in communication (a state indicated by a solid line in FIG. 1); And the fourth port communicates with each other, and the second and third ports communicate with each other (the state shown by the broken line in FIG. 1).

The outdoor heat exchanger (32) is composed of a cross-fin type fin-and-tube heat exchanger. In the outdoor heat exchanger (32), the high-temperature side refrigerant circulating in the high-temperature side refrigerant circuit (20) exchanges heat with the outdoor air.

The receiver (33) is a cylindrical container for storing a refrigerant. The receiver (33) is connected to the outdoor heat exchanger (32) via the inflow pipe (60), and the first liquid side closing valve (35) via the outflow pipe (62).
Is connected to

The inlet end of the inflow pipe (60) is branched into two branch pipes (60a, 60b), and the outlet end is connected to the upper end of the receiver (33). The first branch pipe (60a) of the inflow pipe (60) is connected to the lower end of the outdoor heat exchanger (32). The first branch pipe (60a) is provided with a first inflow check valve (61a). First inflow check valve (61
a) allows only the flow of refrigerant from the outdoor heat exchanger (32) to the receiver (33). The second branch pipe (60b) of the inflow pipe (60) is connected to the first liquid side closing valve (35). This second branch pipe (60b) has a second inflow check valve (61
b) is provided. The second inflow check valve (61b)
Only the flow of the refrigerant from the liquid side closing valve (35) to the receiver (33) is allowed.

The outflow pipe (62) has its inlet end connected to the lower end of the receiver (33), and its outlet end branched into two branch pipes (62a, 62b). The first branch pipe (62a) of the outflow pipe (62) is connected to the lower end of the outdoor heat exchanger (32). The first branch pipe (62a) is provided with the outdoor expansion valve (34). The second branch pipe (62b) of the outflow pipe (62) is connected to the first liquid side closing valve (35). The second branch pipe (62b) is provided with an outflow check valve (63). Outflow check valve (63), receiver (33)
Only the flow of the refrigerant from to the first liquid side closing valve (35) is allowed.

The second liquid-side stop valve (37) is connected to the outflow pipe (6).
The pipe is connected between the outflow check valve (63) and the receiver (33) in the second branch pipe (62b) of 2). On the other hand, the second gas side stop valve (38) is connected to a suction pipe (43) of the compressor unit (40) by piping.

The degassing pipe (64) has one end connected to the upper end of the receiver (33) and the other end connected to the suction pipe (4).
3) Connected to. The gas vent pipe (64) is provided with a gas vent solenoid valve (65). When the gas release solenoid valve (65) is opened and closed, the flow of the refrigerant in the gas release pipe (64) is interrupted.

One end of the pressure equalizing pipe (66) is connected to the solenoid valve (65) for venting the gas venting pipe (64) and the receiver (3).
The other end is connected to the discharge pipe (44). Further, the equalizing pipe (66) has a check valve (67) for equalizing that allows only the flow of the refrigerant from one end to the other end.
Is provided.

The indoor circuit (80) includes an indoor unit (1
It is stored in 2). The indoor circuit (80) includes an indoor heat exchanger (81), which is a heat exchanger for air conditioning, and an indoor expansion valve (82).
Are connected in series by piping. Indoor heat exchanger (8
The lower end of 1) is connected to the indoor expansion valve (82) by piping. The end on the indoor expansion valve (82) side of the indoor circuit (80) is connected to the first liquid side closing valve (35) of the outdoor circuit (30) via the first liquid side connecting pipe (21). I have. On the other hand, the indoor circuit (8
The end on the upper end side of the indoor heat exchanger (81) of (0) is connected to the first gas side shut-off valve (36) of the outdoor circuit (30) via the first gas side communication pipe (22). ing. That is, the indoor heat exchanger (81) is arranged so that the refrigerant flows from the lower end to the upper end during cooling and flows from the upper end to the lower end during heating so that liquid back does not occur.

The cooling circuit (90) includes a cooling unit (1)
3) is stored. In the cooling circuit (90), a cooling heat exchanger (91) and a cooling expansion valve (92) are connected in series by piping. The lower end of the cooling heat exchanger (91) is connected to the cooling expansion valve (92) by piping. That is, the cooling heat exchanger (91) is arranged so that the refrigerant flows from the lower end toward the upper end so that liquid back does not occur.

The refrigeration circuit (100) includes a refrigeration unit (1
4) is stored. The refrigeration circuit (100) is a circuit in which a refrigeration evaporator (101) and a refrigeration expansion valve (102) constituting a low-temperature heat exchanger are connected in series by piping. The upper end of the refrigerating evaporator (101) is connected to the refrigerating expansion valve (102) by piping.

The high temperature side cascade circuit (110) is housed in a cascade unit (15). This high-temperature side cascade circuit (110) has a cascade heat exchanger (111), which is a refrigerant heat exchanger, and a cascade expansion valve (112) connected in series by piping. Cascade heat exchanger (11
The upper end on the primary side of 1) is connected to the cascade expansion valve (112) by piping.

As described above, for the outdoor circuit (30), the second liquid side communication pipe (23) and the second gas side communication pipe (24)
, A cooling circuit (90), a refrigeration circuit (100), and a high-temperature side cascade circuit (110) are connected in parallel with each other. Specifically, one end of the second liquid side communication pipe (23) is connected to the second liquid side closing valve (37). The second liquid-side communication pipe (23) is branched into three at the other end, and has an end on the cooling expansion valve (92) side in the cooling circuit (90) and a refrigeration circuit in the refrigeration circuit (100). The end on the expansion valve (102) side and the cascade expansion valve (1
12) It is connected to the side end.

One end of the second gas side communication pipe (24) is connected to the second gas side closing valve (38). Further, the second gas-side communication pipe (24) is branched into three at the other end, and is connected to an end on the upper end side of the cooling heat exchanger (91) in the cooling circuit (90) and the refrigeration circuit (100). ) Is connected to the lower end of the refrigerating evaporator (101) and the lower end of the cascade heat exchanger (111) in the high-temperature cascade circuit (110). That is, in the cooling heat exchanger (91), the refrigeration evaporator (101), and the cascade heat exchanger (111), the refrigerant inlet is located at the upper end, the refrigerant outlet is located at the lower end, and the high-temperature-side refrigerant flows from above to below. They are connected to flow toward each other.

The indoor heat exchanger (81) and the cooling heat exchanger (9)
1) and the refrigerating evaporator (101) are constituted by a cross-fin type fin-and-tube heat exchanger. In the indoor heat exchanger (81) and the cooling heat exchanger (91),
The high-temperature side refrigerant circulating in the high-temperature side refrigerant circuit (20) exchanges heat with room air. In the refrigeration evaporator (101), the high-temperature side refrigerant circulating in the high-temperature side refrigerant circuit (20) exchanges heat with the air in the refrigerator.

<< Configuration of Low Temperature Refrigerant Circuit >> The low temperature refrigerant circuit (25) includes a low temperature cascade circuit (120), a refrigeration circuit (130), a third liquid side communication pipe (26), and a third liquid side communication pipe (26). It is constituted by a gas side communication pipe (27). The low temperature side cascade circuit (120) and the refrigeration circuit (130) are connected via a third liquid side communication pipe (26) and a third gas side communication pipe (27). The low-temperature side refrigerant circuit (25) is filled with a low-temperature side refrigerant that is a secondary side refrigerant.

The low temperature side cascade circuit (120) is housed in the cascade unit (15). The low temperature side cascade circuit (120) includes a secondary side of the cascade heat exchanger (111), a low temperature side compressor (121), a receiver (123), and a third side.
A liquid side shutoff valve (124) and a third gas side shutoff valve (125) are provided. 1 and 2, "A" in FIG. 2 corresponds to "A" in FIG. 1, and "B" in FIG. 2 corresponds to "B" in FIG.

The discharge side of the low-temperature side compressor (121) is connected to a cascade heat exchanger (11) through a discharge side check valve (122).
The pipe is connected to the upper end of the secondary side in 1). The discharge side check valve (122) allows only the flow of the refrigerant from the low temperature side compressor (121) to the cascade heat exchanger (111). On the other hand, the suction side of the low temperature side compressor (121) is connected to the third gas side closing valve (125) by piping. The lower end of the secondary side of the cascade heat exchanger (111) is connected to the upper part of the receiver (123) by piping. The bottom of the receiver (123) is connected to the third liquid-side stop valve (124) by piping.

The refrigeration circuit (130) includes a refrigeration unit (1
6) is stored. The refrigeration circuit (130) is configured by connecting a refrigeration evaporator (131) and a refrigeration expansion valve (132), which constitute a low-temperature heat exchanger, in series with a pipe. The upper end of the refrigeration evaporator (131) is connected to the refrigeration expansion valve (132) by piping. Refrigeration expansion valve (132) for refrigeration circuit (130)
The end on the side is connected to the third liquid side closing valve (124) of the low temperature side cascade circuit (120) via the third liquid side communication pipe (26). On the other hand, the refrigeration evaporator (13)
The end on the lower end side of 1) is connected to the third gas side shutoff valve (125) of the low temperature side cascade circuit (120) via the third gas side communication pipe (27). In other words, the freezing evaporator (1
31) is connected so that the low-temperature-side refrigerant flows downward from above.

The cascade heat exchanger (111) is constituted by a plate heat exchanger. In the cascade heat exchanger (111), a primary flow path (111a) as an evaporator and a secondary flow path (111b) as a condenser are defined. The primary flow path (111a) forms a low-temperature heat exchanger. As described above, the cascade heat exchanger (111)
The primary side flow path (111a) is connected to the high temperature side refrigerant circuit (20), and the secondary side flow path (111b) is connected to the low temperature side refrigerant circuit (25). The cascade heat exchanger (111) includes a high-temperature side refrigerant flowing through the primary side flow path (111a) and a secondary side flow path (11
This is for exchanging heat with the low-temperature side refrigerant flowing through 1b). That is, the cascade heat exchanger (111) functions as a cascade condenser in the binary refrigeration cycle.

<< Other Configuration >> The outdoor unit (11)
Is provided with an outdoor fan (70) and an outside air temperature sensor (71). The outdoor fan (70) is an outdoor heat exchanger (32)
It is for sending outdoor air to Outside temperature sensor (7
1) is for detecting the temperature of the outdoor air sent to the outdoor heat exchanger (32).

The outdoor circuit (30) housed in the outdoor unit (11) is provided with various sensors. Specifically, the outdoor heat exchanger (32) is provided with an outdoor heat exchanger temperature sensor (72) for detecting the heat transfer tube temperature. The suction pipe (43) has a suction pipe temperature sensor (73) for detecting the suction refrigerant temperature of the compressor (41, 42) and a low pressure for detecting the suction refrigerant pressure of the compressor (41, 42). A pressure sensor (74) is provided. In the discharge pipe (44),
A discharge pipe temperature sensor (75) for detecting the discharge refrigerant temperature of the compressor (41, 42), a high pressure sensor (76) for detecting the discharge refrigerant pressure of the compressor (41, 42), and a high pressure A pressure switch (77) is provided. Degassing pipe (64)
Is provided with a vent tube temperature sensor (78) for detecting the temperature of the refrigerant after passing through the vent gas solenoid valve (65).

The indoor unit (12) is provided with an indoor fan (83) and an indoor air temperature sensor (84). The indoor fan (83) is for sending indoor air to the indoor heat exchanger (81). The indoor air temperature sensor (84) is for detecting the temperature of the indoor air sent to the indoor heat exchanger (81).

The indoor circuit (80) housed in the indoor unit (12) is provided with a temperature sensor. Specifically, the indoor heat exchanger (81) is provided with an indoor heat exchanger temperature sensor (85) for detecting the heat transfer tube temperature. A gas side indoor temperature sensor (86) for detecting the temperature of the gas refrigerant flowing through the indoor circuit (80) is provided near the upper end of the indoor heat exchanger (81) in the indoor circuit (80).

The cooling unit (13) is provided with a cooling fan (93) and a cooling air temperature sensor (94). The cooling fan (93) is for sending indoor air to the cooling heat exchanger (91). The cooling air temperature sensor (94) is for detecting the temperature of the indoor air sent to the cooling heat exchanger (91).

The cooling circuit (90) housed in the cooling unit (13) is provided with a temperature sensor. Specifically, the cooling heat exchanger (91) is provided with a cooling heat exchanger temperature sensor (95) for detecting the heat transfer tube temperature. A gas side cooling temperature sensor (96) for detecting the temperature of the gas refrigerant flowing through the cooling circuit (90) is provided near the upper end of the cooling heat exchanger (91) in the cooling circuit (90).

The refrigerating unit (14) is provided with a refrigerating fan (103) and a refrigerating temperature sensor (104). The refrigeration fan (103) is for sending air in the refrigerator to the refrigeration evaporator (101). The refrigeration temperature sensor (104) is for detecting the temperature of the inside air sent to the refrigeration evaporator (101).

The refrigeration circuit (100) housed in the refrigeration unit (14) is provided with a temperature sensor. Specifically, the refrigerating evaporator (101) is provided with a refrigerating evaporator temperature sensor (105) for detecting the heat transfer tube temperature. Refrigeration evaporator (10 in the refrigeration circuit (100)
Near the lower end of 1), a refrigeration gas side temperature sensor (106) for detecting the temperature of the gas refrigerant flowing through the refrigeration circuit (100)
Is provided.

The high temperature side cascade circuit (110) housed in the cascade unit (15) is provided with a cascade outflow side temperature sensor (113). The cascade outlet temperature sensor (113) is connected to the cascade heat exchanger (1).
This is for detecting the temperature of the high-temperature side refrigerant flowing out of the primary side flow path (111a) of 11).

The refrigerating unit (16) is provided with a refrigerating fan (133) and a refrigerating temperature sensor (134). The freezing fan (133) is for sending air in the freezer to the freezing evaporator (131). The refrigeration temperature sensor (134) is for detecting the temperature of the inside air sent to the refrigeration evaporator (131).

The refrigeration circuit (130) housed in the refrigeration unit (16) is provided with a temperature sensor. Specifically, the refrigerating evaporator (131) is provided with a refrigerating evaporator temperature sensor (135) for detecting the temperature of the heat transfer tube. Refrigeration evaporator (13) in the refrigeration circuit (130)
In the vicinity of the lower end of 1), a refrigeration gas side temperature sensor (136) for detecting the temperature of the gas refrigerant flowing through the refrigeration circuit (130)
Is provided.

The controller (200) controls the operation of the refrigeration system (10) in response to signals from the sensors and command signals from a remote controller or the like. Specifically,
The controller (200) controls the degree of opening of the outdoor expansion valve (34), switches the four-way switching valve (31), and further performs the gas release solenoid valve (65), the oil return solenoid valve (53), and the oil equalization solenoid valve. (55)
Opening and closing operations. Further, the controller (200) controls the capacity of the compressor unit (40).

-Operation- During the operation of the refrigeration system (10), the high-temperature side refrigerant circuit (2
The refrigerant circulates while changing phase in each of 0) and the low-temperature side refrigerant circuit (25), and a vapor compression refrigeration cycle is performed.
Further, the refrigeration apparatus (10) performs an operation by switching between a cooling operation for cooling the indoor air of the indoor unit (12) and a heating operation for heating the indoor air of the indoor unit (12).

<< Cooling operation >> In the cooling operation, in the high-temperature side refrigerant circuit (20), the outdoor heat exchanger (32) is used as a condenser, and the indoor heat exchanger (81), the cooling heat exchanger (91), and the refrigerator are stored. The refrigeration cycle is performed using the evaporator (101) and the cascade heat exchanger (111) as evaporators. On the other hand, in the low-temperature side refrigerant circuit (25), a refrigeration cycle is performed using the cascade heat exchanger (111) as a condenser and the refrigeration evaporator (131) as an evaporator.

During this cooling operation, the four-way switching valve (31) is switched to the state shown by the solid line in FIG. The indoor expansion valve (82), the cooling expansion valve (92), and the refrigeration expansion valve (10
2), cascade expansion valve (112) and refrigeration expansion valve (13
2) is set to the predetermined opening, and the outdoor expansion valve (34) is fully closed. The oil return solenoid valve (53), oil equalizing solenoid valve (55), degassing solenoid valve (65), and liquid supply solenoid valve (69) are normally kept closed. It is opened and closed appropriately.

First, the operation of the high-temperature side refrigerant circuit (20) will be described. Compressor (41,42) of compressor unit (40)
Is operated, the high-temperature side refrigerant compressed by the compressors (41, 42) is discharged to the discharge pipe (44). The high-temperature side refrigerant flows into the outdoor heat exchanger (32) through the four-way switching valve (31). In the outdoor heat exchanger (32), the high-temperature side refrigerant releases heat to outdoor air and condenses. The high-temperature side refrigerant condensed in the outdoor heat exchanger (32) flows into the first branch pipe (60a) of the inflow pipe (60), passes through the first inflow check valve (61a), and passes through the receiver (3).
3). The high-temperature side refrigerant of the receiver (33) flows into the outflow pipe (62). Thereafter, the high-temperature side refrigerant is divided into two flows, one of which flows through the outflow check valve (63) to the first liquid side closing valve (35), and the other flows to the second liquid side closing valve (37).

The high-temperature side refrigerant that has passed through the first liquid side closing valve (35) flows into the indoor circuit (80) through the first liquid side communication pipe (21). In the indoor circuit (80), after the inflowing high-temperature side refrigerant is reduced in pressure by the indoor expansion valve (82), the indoor heat exchanger (8)
1) flows into the indoor heat exchanger (81) from the lower end side. In the indoor heat exchanger (81), the high-temperature side refrigerant flows upward, absorbs heat from room air and evaporates, and cools the room air. In the indoor heat exchanger (81), a sufficient flow of the high-temperature side refrigerant flows, so that the refrigerating machine oil flows without pooling.
The high-temperature side refrigerant evaporated in the indoor heat exchanger (81) flows through the first gas side communication pipe (22), passes through the first gas side closing valve (36), and flows into the outdoor circuit (30). Thereafter, the high-temperature side refrigerant passes through the four-way switching valve (31) and flows into the suction pipe (43).

On the other hand, the high-temperature side refrigerant that has passed through the second liquid side closing valve (37) flows into the second liquid side communication pipe (23). This high-temperature side refrigerant is then divided into three parts, and the cooling circuit (9)
0), refrigeration circuit (100), or high-temperature cascade circuit (11
Flow to 0).

The high-temperature side refrigerant flowing into the cooling circuit (90)
After the pressure is reduced by the cooling expansion valve (92), the cooling heat exchanger (9
The air flows into the cooling heat exchanger (91) from the lower end side of 1). In the cooling heat exchanger (91), the high-temperature side refrigerant flows upward, absorbs heat from the room air, evaporates, and cools the room air. In the cooling heat exchanger (91), a sufficient flow of the high-temperature side refrigerant flows, so that the refrigerating machine oil flows without pooling.

The high-temperature side refrigerant flowing into the refrigeration circuit (100) is depressurized by the refrigeration expansion valve (102), and then flows into the refrigeration evaporator (101) from the upper end side of the refrigeration evaporator (101). I do. At this time, the temperature in the refrigerator is adjusted to a low temperature, and the fluctuation in the temperature in the refrigerator is small.
2) is narrowed down considerably, and the refrigeration evaporator (101)
A small amount of high-temperature refrigerant flows in. Refrigeration evaporator (10
In 1), the high-temperature side refrigerant flows downward, absorbs heat from the air in the refrigerator, evaporates, and cools the air in the refrigerator. The high-temperature side refrigerant flowing through the refrigeration evaporator (101) has a small flow rate, but flows downward and flows out from the lower end portion. It does not flow out together with the refrigerant and remains in the refrigeration evaporator (101). The high-temperature side refrigerant flows out from the lower end side of the refrigerating evaporator (101). However, since the flow rate is small, the high-temperature side refrigerant that does not evaporate does not flow out, and no liquid back occurs.

The high-temperature side refrigerant flowing into the high-temperature side cascade circuit (110) is depressurized by the cascade expansion valve (112), and then decompressed by the cascade heat exchanger (111).
It flows into the cascade heat exchanger (111) from the upper end of 11a). In the cascade heat exchanger (111), the primary flow path (111
The high-temperature side refrigerant flowing through a) flows downward and absorbs heat from the low-temperature side refrigerant flowing through the secondary flow path (111b) and evaporates. Since the cascade expansion valve (112) is considerably throttled according to the refrigeration load in the freezer, the flow rate of the high-temperature side refrigerant flowing through the primary flow path (111a) of the cascade heat exchanger (111) is small. Since the high-temperature side refrigerant flows downward and flows out from the lower end, the refrigerating machine oil does not accumulate in the cascade heat exchanger (111). Although the high-temperature side refrigerant flows out from the lower end side of the cascade heat exchanger (111), since the flow rate is small, the high-temperature side refrigerant that does not completely evaporate does not flow out, and liquid back does not occur.

A cooling heat exchanger (91), a refrigeration circuit (100),
Alternatively, the high-temperature side refrigerant evaporated in the cascade heat exchanger (111) flows into the second gas side communication pipe (24) and merges, and then passes through the second gas side shut-off valve (38) and enters the suction pipe. (43). In the suction pipe (43), the high-temperature side refrigerant sent through the first gas side communication pipe (22)
The high-temperature side refrigerant sent through the gas side communication pipe (24) merges. The high-temperature side refrigerant flowing through the suction pipe (43) is sucked into the compressors (41, 42) of the compressor unit (40). These compressors (41, 42) compress the sucked high-temperature side refrigerant and discharge it again. In the high-temperature side refrigerant circuit (20), such circulation of the high-temperature side refrigerant is repeated.

Next, the operation of the low temperature side refrigerant circuit (25) will be described. When the low temperature side compressor (121) is operated, the compressed low temperature side refrigerant is discharged from the low temperature side compressor (121). The low-temperature side refrigerant passes through the discharge-side check valve (122) and flows into the secondary-side flow path (111b) in the cascade heat exchanger (111). In the cascade heat exchanger (111), the low-temperature refrigerant flowing through the secondary flow path (111b) releases heat to the high-temperature refrigerant flowing through the primary flow path (111a) and condenses. The low-temperature side refrigerant condensed in the cascade heat exchanger (111) passes to the receiver (123)
Flows into. After that, the low-temperature side refrigerant is supplied to the receiver (123).
And flows into the refrigeration circuit (130) through the third liquid side communication pipe (26).

In the refrigeration circuit (130), the inflowing low-temperature side refrigerant is reduced in pressure by the refrigeration expansion valve (132), and then flows into the refrigeration evaporator (131) from the upper end side of the refrigeration evaporator (131). . At this time, the temperature in the freezer is adjusted to a low temperature, and the temperature in the freezer has little fluctuation.
2) is narrowed down considerably, and the freezing evaporator (131)
A small amount of low-temperature refrigerant flows in. Evaporator for refrigeration (13
In 1), the low-temperature refrigerant flows downward, absorbs heat from the air in the freezer and evaporates, and cools the air in the freezer. The low-temperature side refrigerant flowing through the refrigeration evaporator (131) has a small flow rate, but flows downward and flows out from the lower end. It does not flow out with the refrigerant and remains in the freezing evaporator (131). Although the low-temperature side refrigerant flows out from the lower end side of the refrigerating evaporator (131), since the flow rate is small, the low-temperature side refrigerant that does not completely evaporate does not flow out, and no liquid back occurs.

The low-temperature side refrigerant evaporated in the refrigerating evaporator (131) flows into the low-temperature side cascade circuit (120) through the third gas side communication pipe (27). Thereafter, the low-temperature side refrigerant is sucked into the low-temperature side compressor (121). Low temperature compressor (121)
Compresses the sucked low-temperature side refrigerant and discharges it again. In the low-temperature side refrigerant circuit (25), such circulation of the low-temperature side refrigerant is repeated.

<< Heating Operation >> In the heating operation, in the high-temperature side refrigerant circuit (20), the indoor heat exchanger (81) is used as a condenser, the outdoor heat exchanger (32), the cooling heat exchanger (91), and the refrigeration. The refrigeration cycle is performed using the evaporator (101) and the cascade heat exchanger (111) as evaporators. On the other hand, in the low-temperature side refrigerant circuit (25), a refrigeration cycle is performed using the cascade heat exchanger (111) as a condenser and the refrigeration evaporator (131) as an evaporator. The operation of the low-temperature side refrigerant circuit (25) is the same as in the cooling operation.

During this heating operation, the four-way switching valve (31) is switched to the state shown by the broken line in FIG. The indoor expansion valve (82), the cooling expansion valve (92), and the refrigeration expansion valve (10
2), Cascade expansion valve (112), refrigeration expansion valve (13
2) and the outdoor expansion valve (34) is set to a predetermined opening. The oil return solenoid valve (53), oil equalizing solenoid valve (55), degassing solenoid valve (65), and liquid supply solenoid valve (69) are normally kept closed. It is opened and closed appropriately.

The compressor (41, 42) of the compressor unit (40)
When the compressor is operated, the compressed high-temperature refrigerant flows into the compressor (41, 4
From 2), it is discharged to the discharge pipe (44). The discharged high-temperature-side refrigerant passes through the four-way switching valve (31), flows into the indoor circuit (80) through the first gas-side communication pipe (22). The high-temperature side refrigerant that has flowed into the indoor circuit (80) flows into the indoor heat exchanger (81) from the upper end side of the indoor heat exchanger (81). In the indoor heat exchanger (81), the high-temperature side refrigerant radiates heat to the indoor air and condenses, thereby heating the indoor air.

The high-temperature side refrigerant condensed in the indoor heat exchanger (81) passes through the indoor expansion valve (82) and passes through the first liquid side communication pipe (21).
Flows through. The high-temperature side refrigerant of the first liquid side communication pipe (21) is
After passing through the liquid side closing valve (35), it flows into the second branch pipe (60b) of the inflow pipe (60). The high-temperature side refrigerant passes through the second inflow check valve (61b) and flows into the receiver (33). The high-temperature side refrigerant of the receiver (33) flows from the receiver (33) into the outflow pipe (62). Thereafter, the high-temperature side refrigerant is divided into two parts, one of which flows into the first branch pipe (62a) of the outflow pipe (62), and the other flows into the second branch pipe (62b) of the outflow pipe (62).

The high-temperature side refrigerant flowing into the first branch pipe (62a) of the outflow pipe (62) is depressurized by the outdoor expansion valve (34) and then flows into the outdoor heat exchanger (32). In the outdoor heat exchanger (32), the high-temperature side refrigerant absorbs heat from outdoor air and evaporates. The evaporated high-temperature side refrigerant flows into the suction pipe (43) through the four-way switching valve (31).

On the other hand, the second branch pipe (62b) of the outflow pipe (62)
The high-temperature side refrigerant that has flowed into the compressor flows as in the cooling operation.
That is, the high-temperature side refrigerant flows out of the receiver (33), flows through the second liquid side communication pipe (23), is branched, and is cooled.
0), refrigeration circuit (100), or high-temperature cascade circuit (11
Sent to 0). The high-temperature side refrigerant that has flowed into the cooling circuit (90) flows into the cooling heat exchanger (91) from the lower end of the cooling heat exchanger (91), and absorbs heat from room air to evaporate. The high-temperature side refrigerant flowing into the refrigeration circuit (100) is supplied to the refrigeration evaporator (1).
01) flows into the refrigerating evaporator (101) from the upper end side and absorbs heat from the air in the refrigerator to evaporate. The high-temperature side refrigerant that has flowed into the high-temperature side cascade circuit (110) flows into the cascade heat exchanger (111) from the upper end side of the primary flow path (111a) in the cascade heat exchanger (111), and the air in the warehouse Endothermic from and evaporates. Cooling heat exchanger (91), refrigeration evaporator (10
1) or the high-temperature side refrigerant evaporated in the cascade heat exchanger (111) merges in the second gas side communication pipe (24),
The gas flows into the suction pipe (43) through the gas-side stop valve (38).

In the suction pipe (43), the high-temperature side refrigerant evaporated in the outdoor heat exchanger (32) is connected to the cooling heat exchanger (91), the refrigerating evaporator (101), or the cascade heat exchanger (111). The evaporated high-temperature side refrigerant joins. The joined high-temperature side refrigerant is sucked into the compressors (41, 42) of the compressor unit (40).
These compressors (41, 42) compress the sucked high-temperature side refrigerant and discharge it again. In the high-temperature side refrigerant circuit (20), such circulation of the high-temperature side refrigerant is repeated.

As described above, during the heating operation, not only the heat absorbed by the high-temperature side refrigerant from the outdoor air in the outdoor heat exchanger (32) but also the cooling heat exchanger (91), the refrigeration evaporator (101), or The indoor air is heated by the indoor heat exchanger (81) by utilizing the heat absorbed by the high-temperature-side refrigerant from the indoor air and the indoor air in the cascade heat exchanger (111).

Here, during the heating operation, the outdoor heat exchanger (32), the cooling heat exchanger (91), the refrigeration evaporator (101),
In addition, the heat absorption amount of the high-temperature side refrigerant in the cascade heat exchanger (111) may exceed the heat radiation amount of the high-temperature side refrigerant in the indoor heat exchanger (81). In such a case, the outdoor expansion valve (34) is fully closed, and the flow of the high-temperature side refrigerant toward the outdoor heat exchanger (32) is shut off. That is, the cooling heat exchanger (91),
Evaporator for refrigeration (101) and cascade heat exchanger (111)
Is used as an evaporator to reduce the amount of heat absorbed by the high-temperature side refrigerant.

-Effects of Embodiment- According to this embodiment, in the primary side flow path (111a) of the refrigeration evaporator (101) and the cascade heat exchanger (111),
The refrigerant on the primary side flows from the upper part to the lower part and evaporates, and the refrigerant on the secondary side flows from the upper part to the lower part and evaporates in the refrigerating evaporator (131). Evaporator (101), cascade heat exchanger (11
It is possible to prevent the refrigerating machine oil from accumulating in the primary side flow path (111a) and the refrigerating evaporator (131) in 1), and it is possible to easily return the refrigerating machine oil to the compressors (41, 42). . As a result, there is no need to perform oil return control that sacrifices performance, and performance can be maximized.

Further, during the heating operation of the indoor heat exchanger (32), the cold heat obtained from the room is supplied to the refrigeration evaporator (101) or the cascade heat exchanger (111).
Thermal efficiency can be improved.

<Other Embodiments of the Invention>
In the above embodiment, the cooling unit (13) may be omitted.

Further, a plurality of indoor units (12), refrigeration units (14) and refrigerating units (16) may be provided.

Further, the configuration may be such that the low-temperature side refrigerant circuit (25) and the cascade unit (15) are omitted.

[Brief description of the drawings]

FIG. 1 is a refrigerant system diagram showing a high-temperature side refrigerant circuit of a refrigeration apparatus according to an embodiment.

FIG. 2 is a refrigerant system diagram illustrating a low-temperature side refrigerant circuit of the refrigeration apparatus according to the embodiment.

[Explanation of symbols]

 (11) Outdoor unit (20) High-temperature side refrigerant circuit (25) Low-temperature side refrigerant circuit (81) Indoor heat exchanger (101) Evaporator for refrigeration (111) Cascade heat exchanger (111a) Primary flow path (131) Refrigeration evaporator

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kazuhide Nomura 1304 Kanaokacho, Sakai-shi, Osaka Daikin Industries Sakai Works Kanaoka Plant

Claims (4)

[Claims] 1. An air conditioning heat exchanger (81) in which a refrigerant evaporates or condenses, and a low temperature heat exchanger (101, 111a, 131) in which the refrigerant evaporates at a lower temperature than the air conditioning heat exchanger (81). A refrigerating device connected in parallel, wherein the air-conditioning heat exchanger (81) is arranged so that a refrigerant flows from a lower portion to an upper portion during a cooling operation, and the low-temperature heat exchanger (101, 111a, 131) ) Is a refrigeration apparatus characterized in that the refrigerant is arranged so as to flow from the upper part to the lower part. 2. The refrigeration system according to claim 1, wherein the low-temperature heat exchanger is constituted by a refrigeration evaporator (101) for cooling air in the refrigerator. 3. The primary refrigerant circuit (20) according to claim 1, further comprising: an air conditioning heat exchanger (81), a primary refrigerant circuit (20) through which a primary refrigerant circulates. A secondary-side refrigerant circuit (25) having a refrigerating evaporator (131), while circulating a secondary-side refrigerant condensed by evaporation of the primary-side refrigerant, the primary-side refrigerant and the secondary-side refrigerant And a refrigerant heat exchanger (111) for exchanging heat with the refrigerant. The low-temperature heat exchanger includes an evaporator (111) of the refrigerant heat exchanger (111).
A refrigeration apparatus comprising: a) and a refrigeration evaporator (131). 4. The refrigeration evaporator (101) according to claim 3, wherein the primary refrigerant circuit (20) has a compressor (41, 42) and a heat source side heat exchanger (32).
And a heat source unit (11) to which the refrigerant heat exchanger (111) and the air-conditioning heat exchanger (81) are connected to the heat source unit (11). The air-conditioning heat exchanger (81) The primary-side refrigerant condensed in the heat-source-side heat exchanger (32) evaporates to perform a cooling operation, and the primary-side refrigerant condensed in the air-conditioning heat exchanger (81) is refrigerated. ) Or the evaporating section (111) of the refrigerant heat exchanger (111).
A refrigeration apparatus characterized by being configured to perform a heating operation by evaporating in a).